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Positive contrast high-resolution 3D-cine imaging of the cardiovascular system in small animals using a UTE sequence and iron nanoparticles at 4.7, 7 and 9.4 T

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sequence and iron nanoparticles at 4.7, 7 and 9.4 T

Aurélien Trotier, William Lefrançois, Kris van Renterghem, Jean-Michel

Franconi, Eric Thiaudière, Sylvain Miraux

To cite this version:

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T E C H N I C A L N O T E S

Open Access

Positive contrast high-resolution 3D-cine

imaging of the cardiovascular system in

small animals using a UTE sequence and

iron nanoparticles at 4.7, 7 and 9.4 T

Aurélien J. Trotier, William Lefrançois, Kris Van Renterghem, Jean-michel Franconi, Eric Thiaudière and Sylvain Miraux

*

Abstract

Background: To show that 3D sequences with ultra-short echo times (UTEs) can generate a positive contrast whatever the magnetic field (4.7, 7 or 9.4 T) and whatever Ultra Small Particles of Iron Oxide (USPIO) concentration injected and to use it for 3D time-resolved imaging of the murine cardiovascular system with high spatial and temporal resolutions.

Methods: Three different concentrations (50, 200 and 500μmol Fe/kg) of USPIO were injected in mice and static images of the middle part of the animals were acquired at 4.7, 7 and 9.4 T pre and post-contrast with UTE (TE/TR = 0.05/4.5 ms) sequences. Signal-to-Noise Ratio (SNR) and Contrast-to-Noise Ratio (CNR) of blood and static tissus were evaluated before and after contrast agent injection. 3D-cine images (TE/TR = 0.05/3.5 ms, scan time

< 12 min) at 156μm isotropic resolution of the mouse cardiopulmonary system were acquired prospectively with the UTE sequence for the three magnetic fields and with an USPIO dose of 200μmol Fe/kg. SNR, CNR and signal homogeneity of blood were measured. High spatial (104μm) or temporal (3.5 ms) resolution 3D-cine imaging (scan time < 35 min) isotropic resolution were also performed at 7 T with a new sequence encoding scheme. Results: UTE imaging generated positive contrast and higher SNR and CNR whatever the magnetic field and the USPIO concentration used compared to pre-contrast images. Time-resolved 3D acquisition enables high blood SNR (66.6 ± 4.5 at 7 T) and CNR (33.2 ± 4.2 at 7 T) without flow or motion artefact. Coronary arteries and aortic valve were visible on images acquired at 104μm resolution.

Conclusions: We have demonstrated that by combining the injection of iron nanoparticles with 3D-cine UTE sequences, it was possible to generate a strong positive contrast between blood and surrounding tissues. These properties were exploited to produce images of the cardiovascular system in small animals at high magnetic fields with a high spatial and temporal resolution. This approach might be useful to measure the functional cardiac parameters or to assess anatomical modifications to the blood vessels in cardio-vascular disease models.

Keywords: UTE (Ultra-short Echo Time), Iron based nanoparticles, Positive contrast, Cine 3D, Mouse models, Cardio-vascular

* Correspondence:miraux@rmsb.u-bordeaux2.fr

Centre de Résonance Magnétique des Systèmes Biologiques, UMR 5536 CNRS/Université de Bordeaux, 146 rue Léo Saignat, Cedex 33076 Bordeaux, France

© 2015 Trotier et al. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver (http:// creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

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Background

In clinical practice, magnetic resonance angiography (MRA) enhanced by a gadolinium-based contrast agent is the gold standard for many applications [1–3] (MRA of the lower limbs, supra-aortic MRA, dynamic MRA, etc.).

However, the use of this type of contrast agent has two major disadvantages: 1) intra-venous injection entails a risk for the patient to develop nephrogenic systemic fibrosis [4]; 2) first pass extraction and rapid redistribution into the extracellular space limits the time-window of imaging enhanced vasculature [5]. One way to overcome this limitation is to use contrast agents with higher blood half-life. Some gadolinium-based con-trast agents have been developed and validated in pre-clinical models [6].

The use of ultrasmall superparamagnetic iron oxides (USPIOs) can also appear as a good alternative [7, 8]. In patients, numerous studies at 1.5 T described the use of USPIO-based contrast agents for contrast-enhanced angiography [5, 9] and coronary MR angiography [10]. Similar positive contrast was also obtained at low field strength (0.5 T) [11]. Recently, ferumoxytol was used at 3 T for contrast-enhanced high resolution imaging of the cardio-vascular system [12, 13].

In small animals, the use of USPIO-type contrast agents is even more common, but is rarely applied to vascular imaging. In fact, they are mostly used for cell tracking [14, 15] or molecular imaging [16–19]. In these domains, and for reasons of sensitivity, they are rather used as T2* negative contrast agents and at high field strength. Nevertheless, several methods, like off-resonance saturation (ORS) techniques [20–22], have been developed to provide a positive contrast with USPIO-type agents.

These methods use the disturbances of the magnetic field induced by USPIOs. Their limitation, however, is that such disturbances can arise from other sources (air/ tissue interface, imperfections in B0 field homogeneity, etc.). Furthermore, these effects are even more prevalent at high magnetic fields. They may prevent the use of these methods for highly resolved angiography at high magnetic fields commonly used in preclinical studies.

Iron-based contrast agents can produce a positive effect at high fields for angiography if the T2 and T2* effects are limited, and their slight T1 effect availed of. To do this, it is necessary to limit the signal decay caused by the phase-shifts of the spins surrounding the USPIOs. This phenomenon is enhanced by significant and turbulent blood flows in some blood vessels. The best way to limit this signal decay is to drastically re-duce the echo times (TEs) of the MRI sequences.

Ultrashort TE (UTE) pulse sequences allow for signal acquisition with little T2 influence [23] and have been used to probe the T1 effect generated by USPIO. This

approach has shown great promise for in vivo applica-tions particularly in the field of quantitative imaging [24, 25].

The aim of this study was to show that 3D imaging with ultra-short echo times (TE < 0.050 ms) can generate a positive contrast for blood other a wide range of magnetic fields (4.7, 7 or 9.4 T) and USPIO concentrations injected. This method was combined to a new 3D cine UTE encod-ing scheme, to provide 3D time-resolved images of the murine cardiovascular system with either very high spatial or very high temporal resolutions.

Methods

Magnets and gradient systems

Experiments were performed on 4.7, 7 and 9.4-Tesla Bru-ker Biospec Systems (Ettlingen, Germany) equipped with gradient systems capable of 660 mT/m maximum strength and 110-μs rise time. Two different coil systems were used, depending on experiments: (a) a mouse-dedicated probe (birdcage resonator, 35 mm in diameter and 60 mm long at 4.7 T (static images), 7 T (static images) and 9.4 T (static and cine images); (b) a volume resonator (75.4 mm inner diameter, active length 70 mm) operating in quadrature mode was used for transmission, and a four-element (2 × 2) phased array surface coil (outer di-mensions of one coil element: 12 × 16 mm2; total outer dimensions: 26 × 21 mm2) was used for signal reception at 4.7 and 7 T for cine imaging.

In-vivo MR experiments Contrast agents

Three concentrations of Sinerem contrast agent (Guer-bet, Aulnay-sous-bois, France) were used: 50 μmol Fe/ kg - 2.8 mg Fe/kg, 200 μmol Fe/kg - 11.2 mg Fe/kg, and 500 μmol Fe/kg - 28 mg Fe/kg. The r1 and r2 for Sinerem measured in saline were 1.14 ± 0.06 mM−1.sec−1 and 36.46 ± 3.03 mM−1.sec−1 at 4.7 T, 1.13 ± 0.09 mM

−1.sec−1 and 65.21 ± 4.23 mM−1.sec−1 at 7 T and 1.14 ±

0.1 mM−1.sec−1 and 86.23 ± 3.81 mM−1.sec−1 at 9.4 T, respectively.

Animal preparation

All experimental procedures were approved by the Insti-tutional Ethics committee for Animal Care and Use at Bordeaux university, France (Approval No. 5012032-A).

Static imaging

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Cine imaging

Mice (C57BL/ 6, n = 12, body weights: 21–25 g) were anesthetized with isoflurane (1.0 % in air). The ECG signal was picked up using electrodes wrapped around the forelimbs. This signal was converted into a square trigger pulse by a specific monitoring and gating system (SA Instruments, Inc., NY, USA) connected to the spec-trometer. A respiratory sensor was placed under the animal’s thorax. ECG and respiratory signals were visual-ized on a user-interface; cardiac rhythm was stabilvisual-ized (380–420 beats/min) and anesthesia was regulated by modifying the proportion of isoflurane inhaled. A 100-μL volume of 200 μmol Fe/kg was injected through the tail vein. Images were acquired pre and post injection of the contrast agents.

MRI parameters Static imaging

To determine the signal-to-noise ratio and contrast-to-noise ratio obtained before and after injection of the three USPIO concentrations at 4.7, 7 and 9.4 T, non-synchronized images were acquired with 3D UTE sequences on a large field-of-view (FOV) (extending from liver to neck). Imaging parameters are indicated in Table 1.

Cine imaging

3D cine UTE images were acquired at 4.7, 7 and 9.4 T with an isotropic resolution of 156 μm, hereafter called “mid-resolution UTE” and at 7 T with an isotropic reso-lution of 104μm, hereafter called “high-resolution UTE”.

The acquisition scheme of the triggered prospective sequence is shown on Fig. 1. The proposed encoding scheme allows to reconstruct with the same acquisition datas, either Ncine = R-Rinterval/(4 x TR) High Spatial

Resolution images (HSR), or Ncine = R-Rinterval/TR High Temporal Resolution (HTR) images.

Half-projections were sampled in a distribution previ-ously described [26–28], with sampling starting at a pole of the sphere and spiraling down to the other pole as the scan progressed.

To reconstruct HSR images, block of 4 consecutive k-spaces trajectories (named « 1-2-3-4 » for the first R-R interval, « 5-6-7-8 » for the second R-R interval,…) were combined to describe a sphere with the maximum num-bers of projections (52540 per cine). The same encoding was used for each cine HSR images (HSR1, HSR2, …, HSR10).

By using each projections per RR-interval individually, four-times more cine HTR images could be recon-structed with 4 times-less projections (13135). It corre-sponds to the sampling trajectory with the same color code described in Fig. 1c (blue). HTR1, HTR5, … HTR37 have the same sampling trajectory which slightly differs from the HTR2, HTR6, … HTR38 red trajector-ies, HTR3 to HTR 39 green trajectories and HTR4 to HTR40 magenta trajectories.

This method allows to homogeneously distribute pro-jections on the surface of the sphere, both in HSR and HTR images.

Imaging parameters are indicated in Table 1.

Reconstruction procedure

All the UTE data where reconstructed using the follow-ing procedure: k-space data were regridded with an oversampling ratio of 2 using a Kaiser-Bessel kernel [29]. Data were transformed by applying a conventional fast Fourier transform (FFT). Each phased array re-ceiver magnitude image was reconstructed using the

Table 1 Imaging parameters used for static and cine images

Static imaging Cine-imaging

Imaging parameters UTE Mid resolution UTE High resolution UTE

Coil/Magnetic Field Volumetric/ 4.7, 7, 9.4 T Volumetric/9.4 T phased array/ 4.7, 7 T phased array/7 T

TR/TE (ms) 4.5/0.031 3.5/0.031 3.5/0.031

Excitation Pulse/ duration (ms) / FA° square / 0.05 / 15° square / 0.05 / 15° square / 0.05 / 15°

Field of view (mm) 30 × 30 × 30 20 × 20 × 20 20 × 20 × 20

Matrix 128 × 128 × 128 128 × 128 × 128 192 × 192 × 192

Number of projections 51360 18144/cine 52540/cine

Resolution (μm) 234 × 234 × 234 156 × 156 × 156 104 × 104 × 104

Bandwith (Hz/Pixel) 781 781 520

Triggering No ECG ECG

Cine images (N) - 10 10

Excitations (N) 1 1 1

Total acquisition time 3 min 51 s 11 min 20 s 32 min 50 s

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method described above, and then combined by a sum of squares reconstruction.

Image analysis

Signal-to-noise ratio, contrast-to-noise ratio and signal homogeneity measurements

Igor Pro (Wavemetrics, Lake Oswego, OR) data pro-cessing software was used to calculate the apparent signal-to-noise ratio (SNR) for blood, myocardium and muscle. Apparent SNR was defined as the signal inten-sity for the Region Of Interest (ROI) divided by the standard deviation of the noise (measured for an ROI positioned outside the mouse body).

The contrast-to-noise ratio (CNR) for blood com-pared to stationary tissue was defined as CNR = SNR (blood) – SNR (myocardium or muscle). CNR was measured at the level of the aortic arch and jugular veins for static imaging, and in the ventricles for cine imaging.

Signal homogeneity of blood throughout the cycle was assessed using the measurements of the standard deviation for the blood signal in the left and right ventricles and in the aortic arch.

Statistical analysis

Results were compared using an Anova-test.P < 0.05 was considered for a significant difference.

Volume analysis

Volume analysis was performed on 6 mice with a semi-automated segmentation procedure on Amira (Visage Imaging GmbH, Germany) to calculate left ventricular end-diastolic volume, left ventricular end-systolic volume, left ventricular stroke volume (LVSV), left ventricular ejection fraction (LVEF), right ventricular end-diastolic volume, right ventricular end-systolic volume, right ventricular stroke volume (RVSV), and right ventricular ejection fraction (RVEF).

Fig. 1 Acquisition scheme of the 3D ECG-triggered UTE sequence used to reconstruct either 10 High Spatial Resolution cine images or 40 High Temporal Resolution cine images. a Blocks of 4 Free Induction Decays (FIDs) corresponding to 4 k-space trajectories (named « 1-2-3-4 » for the first R-R interval, « 5-6-7-8 » for the second R-R interval…) were repeatedly acquired 10 times along one R-R interval. b (up) Point surface showing the end-point of the acquired half-projections in a 3D k-space and (bottom) the corresponding projections on the kx-kyplane, acquired 10 times

for one R-R interval. The reconstructed images display high space resolution (HSR) and lower time resolution. c (up) Point surface showing the ends of the first acquired half-projection of each block in a 3D k-space and (bottom) the corresponding projections on the kx-kyplane of the end-point of

trajectories. The reconstructed images display higher time resolution (HR) at the expense of space-resolution. d Projections on the kx-kyplane of the

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Results

Static imaging– pre and post contrast with UTE sequences

Images were acquired in a zone extending from the liver to the neck. Three different concentrations of contrast agents were used, and the images acquired at 9.4 T pre-and post contrast agent injection with UTE sequences are shown in Fig. 2. Before injecting the contrast agent, the blood vessels and the blood inside the ventricles were not readily visible. After injection of the contrast agent, whatever the concentration injected, the blood in the various blood vessels was visible with the UTE sequence with an intense signal. This signal was highly homogeneous, whether in zones with high turbulence, such as the aortic arch (Fig. 2, small arrow), or in blood vessels with slow-flow, such as the jugular veins. No artefact related to blood flow or movement was visible on the images.

It should also be noted that the liver (Fig. 2, dashed arrow) always appears with a positive contrast and that its signal increases with USPIO concentration.

The same experiments were performed at 4.7 T, 7.0 T and 9.4 T, and the signal-to-noise ratio was measured for blood (aortic arch, jugular vein) and for the muscles. The blood-to-muscle contrast-to-noise ratios under the different conditions are indicated in Fig. 3.

Before contrast agent injection, contrast-to-noise ra-tio was very low (in the range of -2). After injecra-tion, whatever the magnetic field and the concentration of nanoparticles used, the contrast-to-noise ratio was always positive, and greater than or equal to 18. In-creasing the concentration raised the contrast-to-noise ratio, at all magnetic fields (p < 0.05 for 200 μmol Fe/kg vs. 500 μmol Fe/kg). The highest concentration gave a

better contrast-to-noise ratio, always greater than 40, whatever the magnetic field. Increasing the magnetic field slightly decreased the contrast-to-noise ratio, but this change was not significant.

It must be noted that for the lowest Sinerem concen-tration (50 μmol Fe/kg), the contrast varied slightly during the experiment (data not shown). This tended to decrease about 30 % over one hour with the UTE sequence. In contrast, the CNR measurements remained stable for at least one hour after injection for the two high-est concentrations of contrast agent.

Cine imaging Mid-resolution UTE

3D-cine images at 156 μm isotropic resolution were acquired prospectively with the UTE sequence for the three magnetic fields tested before and after contrast agent injection. The intermediate concentration of contrast agent (200 μmol Fe/kg) was used for the im-ages shown in Fig. 4, but similar results were obtained with the highest concentration. Slices were extracted during systole and diastole in two orientations (short axis and long axis) and are shown for the three mag-netic fields. The acquisition times for these images were around 12 min.

Before injection, a contrast to noise ratio around -3 was obtained. After injection, and whatever the mag-netic field, a positive contrast between myocardial blood and the myocardial wall was obtained at all times throughout the cardiac cycle (Table 2). The signal was also highly homogeneous, in both the blood vessels and in the heart cavities. For example, during a given ex-periment at 7 T, the standard deviation of the signal measured in the ventricles and the aortic arch during

Fig. 2 3D UTE images at 9.4 T showing the heart and the liver of a mouse. Images were acquired before and after injection of USPIO at 50, 200 and 500μmol Fe/kg, without cardiac or respiratory synchronization. The small arrow indicates the aortic arch and the dashed arrow indicates the liver

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the cardiac cycle gave a value between 1.43 and 2.2 with an apparent SNR of 70.

The images at 4.7 T and 7 T were of comparable quality, while at 9.4 T the signal-to-noise ratio and the contrast-to-noise ratio were lower. This discrepancy can be ex-plained by the use of dedicated 4-channel receiver coils at 4.7 and 7 T only.

High-resolution UTE

Images at 104-μm isotropic resolution were acquired at 7 T (Fig. 5). Such a resolution necessitated 35 min ac-quisition. As expected, the concentration of contrast agent was sufficient during the experiment to enable a very good apparent signal-to-noise ratio for the blood (40.2 ± 2.3) and a good contrast-to-noise ratio between the blood and the myocardium (15.8 ± 2.0).

The spatial resolution appears to be effectively im-proved compared to images acquired at a resolution of 156μm. This improvement in resolution can be used to perform precise volumetry (LVSV (μL) = 27.1 ± 3.2; LVEF (%) = 64.1 ± 4.2; RVSV (μL) = 27.4 ± 3.6; RVEF (%) = 61.8 ± 5.2).

It can also be used to better appreciate the deforma-tions of the aortic arch during the cardiac cycle and to distinguish aortic valve (arrowheads, Fig. 5a N°6) and to track the left and right coronary arteries (arrows, Fig. 5b).

Movies showing the 4D-cine images are available as Additional file 1, Additional file 2, Additional file 3 and Additional file 4.

Finally, with the acquisition method used, although it decreases the spatial resolution and the signal-to-noise ratio due to 4 times less number of projections per cine, it is also possible to reconstruct a greater number of images per cardiac cycle. In the videos shown in Additional file 3 and Additional file 4, forty images were reconstructed per R-R interval.

Discussion

This article demonstrates that by combining the use of a UTE 3D imaging sequence with USPIO-based contrast agents it is possible to achieve a strong Signal-to-Noise Ratio and a strong positive contrast at high magnetic fields (4.7 and 9.4 T), and thus to generate highly temporally Fig. 3 Contrast-to-noise ratio between blood in the aortic arch and muscle, obtained with UTE sequences before and after injection of USPIO at 4.7, 7 and 9.4 T and for different injection doses (200 and 500μmol Fe/kg). p values lower than 0.05 are indicated by an asterisk

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and spatially resolved images of the cardiovascular system in small animals.

The term“apparent SNR” instead of SNR was used in this article because the method of SNR calculation did not take into account the spatial variance of noise of phased-array coils. However, as mentioned by Kellman et al. [30], this spatial variation is important only when parallel reconstruction is used which was not the case in our experiments.

We believe that the contrast obtained here is greater than those described to date in the literature on mouse cardiac MRI [31–34].

Up to now, iron nanoparticles have mainly been used through their T2* effect, which allows their presence to be detected at high magnetic fields (≥4.7 T), in particular in the field of cellular imaging. Recently, Strobel et al. [35] exploited the T1 effect of iron oxide particles to detect pulmonary inflammation. However, in these ex-periments, the increase in signal for the lung appears weak, probably due to a low concentration of contrast agent in the observed zone.

At 3 T, Girard et al. [24] showed that, with a subUTE sequence, it is possible to have a positive T1 effect and to exploit it to demonstrate tumor targeting in vivo. At lower magnetic fields (< 3 T) [6, 36, 37], and recently at 3 T [12, 13], iron nanoparticles have been shown to be good contrast agents for angiography with classical gradient echo sequences.

In these studies, to limit the susceptibility effect, contrast agent was injected at doses between 50 and 100 μmol Fe/kg. At high magnetic fields, as used here, a dose of 50μmol Fe/kg gives a positive contrast with a UTE sequence. However, this contrast is lower than with other concentrations and decreases over time. It can therefore limit the acquisition of high-resolution images because a high contrast is necessary during more than 30 min.

With higher doses of injections, the contrast-to-noise ratio was significantly increased for all magnetic fields,

Table 2 CNR values between the blood in the ventricles and the myocardial wall obtained with the UTE sequence at 156μm isotropic resolution without USPIO and after injection of USPIO at 200μmol Fe/kg

CNR (left ventricule - left myocardium)

End-diastole End-systole

UTE 4.7 T without USPIO −2.6 ± 0.6 −4.0 ± 0.9 USPIO 200μmol Fe/kg 31.4 ± 3.8 30.2 ± 2.2 UTE 7 T without USPIO −2.5 ± 0.7 −3.9 ± 0.6 USPIO 200μmol Fe/kg 33.2 ± 4.2 29.2 ± 2.5 UTE 9.4 T without USPIO −2.1 ± 0.5 −3.9 ± 0.9 USPIO 200μmol Fe/kg 16.3 ± 5.8 15.2 ± 3.2

Fig. 5 a 3D ECG-gated cine image as a function of cardiac cycle, obtained at 7 T at 104μm isotropic resolution after injection of USPIO at 200μmol Fe/kg. Short axis: upper panel; long axis: lower panel. No respiratory gating was used. The arrow (image 6) indicates the aortic valve. b Slices extracted from a 3D volume showing the coronary arteries (right coronary arteries: arrow in upper image; right coronary arteries and left cor-onary arteries: arrows lower image). The scale-bar represents 1 cm

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and it remained constant for a duration compatible with high-resolution cardiac cine image acquisition (> 40 min). Although the doses injected in this study were higher than the doses used for clinical angiography, they remained significantly lower than the doses used forin-vivo targeting imaging (1000 μmol Fe/kg) [37].

Compared to gadolinium chelate-type contrast agents, the major advantage of iron nanoparticles is their much longer half-life in the blood, which permits 3D-cine acquisition in small animal. Other gadolinium-based contrast agents have been developed which have a longer half-life. For example, reports are given for p846 [6], a blood pool contrast agent consisting of a single gadolinium ion in a macrocyclic 3-armed chelate, developed by Guerbet (Aulnay-sous-bois, France), or gadolinium-loaded liposomes [31, 32]. However, none of these agents has been approved for clinical use, and their long-term innocuousness has yet to be confirmed. In contrast, a large variety of iron-based nanoparticles has been developed with various sizes, coating compounds and surface charges (Sinerem ®, Endorem ®, P904 ® from Guerbet, Resovist ® and Supravist ® from Bayer Schering, Clariscan ® from Amersham Health and Ferumoxytol ® from AMAG Pharmaceuticals, …) [38] and tested on small animals or humans. Among them, P904 is still avail-able for preclinical imaging (Chematech, Dijon, France). Ferumoxitol has recently gained in interest in clinical MRI [39] due to its U.S. FDA approval as an iron supplement for patients with chronic kidney disease. Moreover, its higher relaxivity compared to Sinerem (r1 = 2 mM−1s−1at 7 T [25]) combined with a prolonged circulating half-life (14–15 h), should make it an excellent contrast agent for high field MRI.

Since such contrast agents are strongly paramagnetic, ultra-short echo times are needed to achieve significant positive contrast. The UTE sequence used in this study has several advantages. The use of radial encoding with sampling from the center of the k-space, combined with 3D imaging without slice selection and the use of a short excitation pulse (50 μs) makes it possible to generate extremely short TEs, less than 0.05 ms in this study. In small animals, this type of sequence has already been used for 2D-cine cardiac imaging and makes it possible to observe a time-of-flight effect. However, resolution of 2D MRI is often limited in the third dimension of space, and the TE is increased (> 0.3 ms), which can limit its use-fulness when a contrast agent with a strong susceptibility effect is injected.

The other advantage of UTE sequences is their low sensitivity to several artefacts due to motion or blood flow. Thus, the signal from blood in areas particularly prone to turbulent flow appears quite homogeneous. This makes it possible to unambiguously measure the volume of the ventricles, whereas in conventional

bright-blood images measurements can be affected by errors due to signal loss caused by significant phase-shifts of the spins in blood. The method presented here (UTE + USPIO) could thus be used for phase imaging in regions of extremely turbulent blood flow. Kadbi et al. [40] have already demonstrated the efficacy of UTE sequences to measure blood flow. However, to obtain a significant time-of-flight effect, they had to introduce a slice selection into the UTE sequence, thus increasing the value of TE. The method used here, using both non-selective volume excitation and USPIO injection, allows shorter TE and would be also useful for blood flow quantification.

Finally, we have shown that the combination of the 3D UTE sequence with the injection of an USPIO-type contrast agent makes it possible to generate very high spatial resolution, even though iron-based nanoparti-cles are known to diminish this resolution, particularly at high magnetic fields. Thus, by using significantly lower voxel sizes than those used to date in the litera-ture [34, 41], a particularly precise ventricular volume can be determined (with semi-automated segmenta-tion) in a relatively short acquisition time (around 12 min for a resolution of 156μm, and around 35 min for a resolution of 104μm). This should make it possible to study numerous models of heart diseases. In addition, the coronary arteries (right and left) are clearly visible at high resolution (Fig. 5b) as a function of the heart rate, whereas previous coronary images in small animals were acquired only during diastole [42, 43].

Among the limitations of the method proposed, the acquisition time for radial UTE images appears long compared to classical Cartesian methods, particularly when high spatial resolutions are necessary. However, as previously shown [44], radial methods are favorable to the use of compressed sensing reconstruction algorithms which can be used to limit the acquisition time.

One caveat of this study is that the doses of contrast agent used are higher than those commonly used for USPIO-based angiography in humans. However, they remain lower than those used in targeting imaging. In the absence of additional data, it is not possible today to use these doses as a first-pass agent for angiography in humans. However, doses between 50 and 100 μmol Fe/ kg combined with 3D UTE imaging sequences, particu-larly at magnetic fields of 3 T or higher, should make it possible to image human vascular systems with temporal and spatial resolution which could be higher than those currently used in the clinical practice.

Conclusion

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contrast between the blood and surrounding tissues. These signals and their high contrast were exploited to produce images of the cardiovascular system in small animals at high magnetic fields with a high spatial and temporal resolution. It can be useful for measuring the functional cardiac parameters or for assessing anatom-ical modifications to the blood vessels in disease models.

Additional files

Additional file 1: Movie generated from the ten 3D cine images at 104μm isotropic resolution. Transverse orientation. The slices go from the aortic arch to the apex of the heart.

Additional file 2: Movie generated from the ten 3D cine images at 104μm isotropic resolution. The slices go in the direction of the coronal plane.

Additional file 3: Movie of the heart in the direction of the short axis. The same data are used for the images at 104μm isotropic resolution, but here, forty images per cycle were reconstructed with high temporal resolution encoding scheme.

Additional file 4: Movie of the heart in the direction of the long axis. The same data are used for the images at 104μm isotropic resolution, but here, forty images per cycle were reconstructed with high temporal resolution encoding scheme.

Abbreviations

UTE:Ultra-short echo time; FID: Free induction decay; ROI: Region-of-interest; TE: Echo time; TR: Repetition time.

Competing interests

The authors declare that they have no competing interests. Authors’ contributions

AJT and SM designed 3D UTE sequence, acquired and reconstructed in vivo data. WL, KVR and SM have participated to the design of experiments and collection of data. SM and AJT have analyzed and interpreted data and performed statistical analysis. SM, ET and JMF have helped to draw the manuscript. All authors read and approved the final manuscript. Acknowledgements

This work was supported by a public grant, Translational Research and Advanced Imaging Laboratory, which is part of the French National Research Agency’s Investments for the Future Program (“NewFISP”; ANR- 10-LABX-57). The authors thank Dr Julie Magat for technical assistance at 9.4 T. Received: 30 March 2015 Accepted: 24 June 2015

References

1. Nielsen YW, Thomsen HS. Contrast-enhanced peripheral MRA: technique and contrast agents. Acta Radiol. 2012;53:769–77.

2. Kramer JH, Arnoldi E, François CJ, Wentland AL, Nikolaou K, Wintersperger BJ, et al. Dynamic and static magnetic resonance angiography of the supra-aortic vessels at 3.0 T: intraindividual comparison of gadobutrol, gadobenate dimeglumine, and gadoterate meglumine at equimolar dose. Invest Radiol. 2013;48:121–8.

3. Gaens ME, Backes WH, Rozel S, Lipperts M, Sanders SN, Jaspers K, et al. Dynamic contrast-enhanced MR imaging of carotid atherosclerotic plaque: model selection, reproducibility, and validation. Radiology. 2013;266:271–9. 4. Kaewlai R, Abujudeh H. Nephrogenic systemic fibrosis. AJR Am J Roentgenol.

2012;199:W17–23.

5. Prince MR, Zhang HL, Chabra SG, Jacobs P, Wang Y. A pilot investigation of new superparamagnetic iron oxide (ferumoxytol) as a contrast agent for cardiovascular MRI. J Xray Sci Technol. 2003;11:231–40.

6. Kinner S, Maderwald S, Parohl N, Albert J, Corot C, Robert P, et al. Contrast-enhanced magnetic resonance angiography in rabbits:

evaluation of the gadolinium-based agent p846 and the iron-based blood pool agent p904 in comparison with gadoterate meglumine. Invest Radiol. 2011;46:524–9.

7. Neuwelt EA, Hamilton BE, Varallyay CG, Rooney WR, Edelman RD, Jacobs PM, et al. Ultrasmall superparamagnetic iron oxides (USPIOs): a future alternative magnetic resonance (MR) contrast agent for patients at risk for nephrogenic systemic fibrosis (NSF)? Kidney Int. 2009;75:465–74.

8. Corot C, Robert P, Idée J, Port M. Recent advances in iron oxide nanocrystal technology for medical imaging. Adv Drug Deliv Rev. 2006;58:1471–504. 9. Bremerich J, Bilecen D, Reimer P. MR angiography with blood pool contrast

agents. Eur Radiol. 2007;17:3017–24.

10. Wagner M, Wagner S, Schnorr J, Schellenberger E, Kivelitz D, Krug L, et al. Coronary MR angiography using citrate-coated very small superparamagnetic iron oxide particles as blood-pool contrast agent: initial experience in humans. J Magn Reson Imaging. 2011;34:816–23.

11. Clarke SE, Weinmann HJ, Dai E, Lucas AR, Rutt BK. Comparison of two blood pool contrast agents for 0.5-T MR angiography: experimental study in rabbits. Radiology. 2000;214:787–94.

12. Han F, Rapacchi S, Khan S, Ayad I, Salusky I, Gabriel S, et al. Four-dimensional, multiphase, steady-state imaging with contrast enhancement (MUSIC) in the heart: A feasibility study in children. Magn Reson Med. 2014, doi: 10.1002/mrm.25491.

13. Ruangwattanapaisarn N, Hsiao A, Vasanawala SS. Ferumoxytol as an off-label contrast agent in body 3T MR angiography: a pilot study in children. Pediatr Radiol. 2015;45(6):831–9. doi:10.1007/s00247-014-3226-3. 14. Josephson L, Tung CH, Moore A, Weissleder R. High-efficiency intracellular

magnetic labeling with novel superparamagnetic-Tat peptide conjugates. Bioconjug Chem. 1999;10:186–91.

15. Lewin M, Carlesso N, Tung CH, Tang XW, Cory D, Scadden DT, et al. Tat peptide-derivatized magnetic nanoparticles allow in vivo tracking and recovery of progenitor cells. Nat Biotechnol. 2000;18:410–4.

16. Peng XH, Qian X, Mao H, Wang AY. Targeted magnetic iron oxide nanoparticles for tumor imaging and therapy. Int J Nanomedicine. 2008;3:311–21.

17. Weinstein JS, Varallyay CG, Dosa E, Gahramanov S, Hamilton B, Rooney WD, et al. Superparamagnetic iron oxide nanoparticles: diagnostic magnetic resonance imaging and potential therapeutic applications in neurooncology and central nervous system inflammatory pathologies, a review. J Cereb Blood Flow Metab. 2010;30:15–35.

18. Qiao J, Li S, Wei L, Jiang J, Long R, Mao H, et al. HER2 targeted molecular MR imaging using a de novo designed protein contrast agent. PLoS One. 2011;6:e18103.

19. Sun C, Lee JS, Zhang M. Magnetic nanoparticles in MR imaging and drug delivery. Adv Drug Deliv Rev. 2008;60:1252–65.

20. Farrar CT, Dai GP, Novikov M, Rosenzweig A, Weissleder R, Rosen BR, et al. Impact of field strength and iron oxide nanoparticle concentration on the linearity and diagnostic accuracy of off-resonance imaging. NMR Biomed. 2008;21:453–63.

21. Stuber M, Gilson WD, Schar M, Kedziorek DA, Hofmann LV, Shah S, et al. Positive contrast visualization of iron oxide-labeled stem cells using inversion-recovery with ON-resonant water suppression (IRON). Magn Reson Med. 2007;58:1072–7.

22. Zurkiya O, Hu XP. Off-resonance saturation as a means of generating contrast with superparamagnetic nanoparticles. Magn Reson Med. 2006;56:726–32.

23. Tyler DJ, Robson MD, Henkelman RM, Young IR, Bydder GM. Magnetic resonance imaging with ultrashort TE (UTE) PULSE sequences: technical considerations. J Magn Reson Imaging. 2007;25:279–89. Review. 24. Girard OM, Du J, Agemy L, Sugahara KN, Kotamraju VR, Ruoslahti E, et al.

Optimization of iron oxide nanoparticle detection using ultrashort echo time pulse sequences: comparison of T1, T2*, and synergistic T1-T2* contrast mechanisms. Magn Reson Med. 2011;65:1649–60.

25. Gharagouzloo CA, McMahon PN, Sridhar S. Quantitative contrast-enhanced MRI with superparamagnetic nanoparticles using ultrashort time-to-echo pulse sequences. Magn Reson Med. 2014, doi: 10.1002/mrm.25426. 26. Saff EB, Kuijlaars ABJ. Distributing many points on a sphere. Math Intell.

1997;19:5–11.

27. Nielles-Vallespin S, Weber MA, Bock M, Bongers A, Speier P, Combs SE, et al. 3D radial projection technique with ultrashort echo times for sodium MRI: clinical applications in human brain and skeletal muscle. Magn Reson Med. 2007;57:74–81.

(11)

28. Koktzoglou I. 4D Dark blood arterial wall magnetic resonance imaging: methodology and demonstration in the carotid arteries. Magn Reson Med. 2013;69:956–65.

29. Beatty PJ, Nishimura DG, Pauly JM. Rapid gridding reconstruction with a minimal oversampling ratio. IEEE Trans Med Imaging. 2005;24:799–808. 30. Kellman P, McVeigh ER. Image reconstruction in SNR units: a general

method for SNR measurement. Magn Reson Med. 2005;54:1439–47. 31. Bucholz E, Ghaghada K, Qi Y, Mukundan S, Johnson GA. Four-dimensional

MR microscopy of the mouse heart using radial acquisition and liposomal gadolinium contrast agent. Magn Reson Med. 2008;60:111–8.

32. Bucholz E, Ghaghada K, Qi Y, Mukundan S, Rockman HA, Johnson GA. Cardiovascular phenotyping of the mouse heart using a 4D radial acquisition and liposomal Gd-DTPA-BMA. Magn Reson Med. 2010;63:979–87. 33. Hoerr V, Nagelmann N, Nauerth A, Kuhlmann MT, Stypmann J, Faber C.

Cardiac-respiratory self-gated cine ultra-short echo time (UTE) cardiovascular magnetic resonance for assessment of functional cardiac parameters at high magnetic fields. J Cardiovasc Magn Reson. 2013;15:59.

34. Feintuch A, Zhu Y, Bishop J, Davidson L, Dazai J, Bruneau BG, et al. 4D cardiac MRI in the mouse. NMR Biomed. 2007;20:360–5.

35. Strobel K, Hoerr V, Schmid F, Wachsmuth L, Löffler B, Faber C. Early detection of lung inflammation: exploiting T1-effects of iron oxide particles using UTE MRI. Magn Reson Med. 2012;68:1924–31.

36. Ersoy H, Jacobs P, Kent CK, Prince MR. Blood pool MR angiography of aortic stent-graft endoleak. AJR Am J Roentgenol. 2004;182:1181–6.

37. Sigovan M, Boussel L, Sulaiman A, Sappey-Marinier D, Alsaid H, Desbleds-Mansard C, et al. Rapid-clearance iron nanoparticles for inflammation imaging of atherosclerotic plaque: initial experience in animal model. Radiology. 2009;252:401–9.

38. Neuwelt EA, Hamilton BE, Varallyay CG, Rooney WR, Edelman RD, Jacobs PM, et al. Ultrasmall superparamagnetic iron oxides (USPIOs): a future alternative magnetic resonance (MR) contrast agent for patients at risk for nephrogenic systemic fibrosis (NSF)? Kidney Int. 2009;75:465–74. Review. 39. Bashir MR, Bhatti L, Marin D, Nelson RC. Emerging applications for ferumoxytol

as a contrast agent in MRI. J Magn Reson Imaging. 2015;41:884–98. 40. Kadbi M, Wang H, Negahdar M, Warner L, Traughber M, Martin P, et al. A

novel phase-corrected 3D cine ultra-short te (UTE) phase-contrast MRI technique. In: Proceeding of the Engineering in Medicine and Biology Society (EMBC). San Diego, USA: 2012 Annual International Conference of the IEEE; 2012. p. 77–81.

41. Miraux S, Calmettes G, Massot P, Lefrançois W, Parzy E, Muller B, et al. 4D retrospective black blood trueFISP imaging of mouse heart. Magn Reson Med. 2009;62:1099–105.

42. Ruff J, Wiesmann F, Lanz T, Haase A. Magnetic resonance imaging of coronary arteries and heart valves in a living mouse: techniques and preliminary results. J Magn Reson. 2000;146:290–6.

43. Cochet H, Montaudon M, Laurent F, Calmettes G, Franconi JM, Miraux S, et al. In vivo MR angiography and velocity measurement in mice coronary arteries at 9.4 T: assessment of coronary flow velocity reserve. Radiology. 2010;254:441–8.

44. Nam S, Akçakaya M, Basha T, Stehning C, Manning WJ, Tarokh V, et al. Compressed sensing reconstruction for whole-heart imaging with 3D radial trajectories: a graphics processing unit implementation. Magn Reson Med. 2013;69:91–102.

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